The present disclosure provides a coacervate composition containing a protein drug, gelatin A, sodium alginate and an acid and a wound-healing agent including the same. The coacervate composition according to the present disclosure can be useful as a wound-healing material delivery system for effectively delivering a protein drug, particularly epidermal growth factor, to a wound site in the wound-healing field.

The present disclosure provides a coacervate composition containing a protein drug, gelatin A, sodium alginate and an acid and a wound-healing agent including the same. The coacervate composition according to the present disclosure can be useful as a wound-healing material delivery system for effectively delivering a protein drug, particularly epidermal growth factor, to a wound site in the wound-healing field.

Provided is a bioink comprising a mixture comprising a collagen and a polysaccharide, and a polyhedral oligomeric silsesquioxane (POSS), a hydrogel matrix formed from a bioink comprising a mixture comprising a collagen and a polysaccharide, and a polyhedral oligomeric silsesquioxane (POSS), a 3D biomaterial scaffold comprising a hydrogel matrix of the disclosure as a first hydrogel layer and a hydrogel matrix of the disclosure as a second hydrogel layer, optionally having an intervening layer between the first hydrogel layer and the second hydrogel layer, and methods of forming and using same.

Provided is a bioink comprising a mixture comprising a collagen and a polysaccharide, and a polyhedral oligomeric silsesquioxane (POSS), a hydrogel matrix formed from a bioink comprising a mixture comprising a collagen and a polysaccharide, and a polyhedral oligomeric silsesquioxane (POSS), a 3D biomaterial scaffold comprising a hydrogel matrix of the disclosure as a first hydrogel layer and a hydrogel matrix of the disclosure as a second hydrogel layer, optionally having an intervening layer between the first hydrogel layer and the second hydrogel layer, and methods of forming and using same.

The present invention relates to two-dimensional and three-dimensional shaped parts and composite materials made of popcorn and synthetic and/or natural binding agents which are cured in automatic moulding machines or similar pressing installations by means of radio wave technology or microwaves. By means of these technologies, light-weight, two-dimensional and three-dimensional shaped parts and composite materials can be produced for packaging, as interior and exterior parts (for example in automobile and mobile-home construction), shock absorbers, space-dividing elements, furniture, consumer goods, for the building trade of for heat insulation.

The present invention relates to two-dimensional and three-dimensional shaped parts and composite materials made of popcorn and synthetic and/or natural binding agents which are cured in automatic moulding machines or similar pressing installations by means of radio wave technology or microwaves. By means of these technologies, light-weight, two-dimensional and three-dimensional shaped parts and composite materials can be produced for packaging, as interior and exterior parts (for example in automobile and mobile-home construction), shock absorbers, space-dividing elements, furniture, consumer goods, for the building trade of for heat insulation.

Compositions comprised of: (i) a blend of fibrinogen, thrombin, wherein the blend is in the form of a plurality of particles, and (ii) a hydrophobic dispersant, wherein the composition is in the form of a paste at at-least one temperature in the range of 10° C., to 37° C., are disclosed herein. Methods for preparing a fibrin adhesive sealant in/on an injured tissue are further disclosed.

Compositions comprised of: (i) a blend of fibrinogen, thrombin, wherein the blend is in the form of a plurality of particles, and (ii) a hydrophobic dispersant, wherein the composition is in the form of a paste at at-least one temperature in the range of 10° C., to 37° C., are disclosed herein. Methods for preparing a fibrin adhesive sealant in/on an injured tissue are further disclosed.

A method for producing a 3D-printed tissue substitute is disclosed, utilizing a 3D printing device including a tank including a yield stress fluid in which the material is printed, the printing material delivered by the cartridge includes polyvinyl alcohol and gelatin, the method including a step following which, after printing the material in the yield stress fluid, a printed intermediate device is solidified in the yield stress fluid by lowering the temperature of the tank. The intermediate device is removed from the tank, rinsed and dried in order to obtain the tissue substitute.

A method for producing a 3D-printed tissue substitute is disclosed, utilizing a 3D printing device including a tank including a yield stress fluid in which the material is printed, the printing material delivered by the cartridge includes polyvinyl alcohol and gelatin, the method including a step following which, after printing the material in the yield stress fluid, a printed intermediate device is solidified in the yield stress fluid by lowering the temperature of the tank. The intermediate device is removed from the tank, rinsed and dried in order to obtain the tissue substitute.